Biogeochemistry of serpentine soils /:
Soils have various functions in all ecosystems, particularly for environmental quality and human health. The parent materials of serpentine soils are characterized by much higher contents of elements such as Mg, Fe, Cr, Ni, Co, and Mn, and thus the derived soils display potentially ecological or env...
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| Format: | Elektronisch E-Book |
| Sprache: | English |
| Veröffentlicht: |
New York :
Nova Science Publishers, Incorporated,
2018.
|
| Schriftenreihe: | Environmental science, engineering and technology series.
Environmental Science, Engineering and Technology Ser. |
| Schlagworte: | |
| Online-Zugang: | Volltext |
| Zusammenfassung: | Soils have various functions in all ecosystems, particularly for environmental quality and human health. The parent materials of serpentine soils are characterized by much higher contents of elements such as Mg, Fe, Cr, Ni, Co, and Mn, and thus the derived soils display potentially ecological or environmental risk due to high levels of geogenic heavy metals, low concentrations of P and K, low Ca/Mg ratios, unique flora, and unstable landscape. Serpentine soils can be produced by ultramafics alone and also by hydrothermally altered ultramafics in the presence of serpentines, but they are abundant in ophiolite belts along tectonic plate margins. To sustain natural resources such as serpentine soils, we need a better understanding for the impact of serpentine soils on (1) the pedosphere and rhizosphere, (2) ecology and restoration, (3) biogeochemical cycling of elements, (4) environmental quality, crop quality, food safety, and human health, and (5) phyto-accumulation and agromining of heavy metals (i.e., nickel) worldwide. Hence, the purpose of this book is to study the biogeochemical characteristics of serpentine soils. In the beginning, the authors introduce the basic knowledge of these soils including pedogenesis, mineral weathering, morphology, and classification. Moreover, bioavailability, plant uptake, and human health risk were discussed for the enriched heavy metals in serpentine soil. Finally, applications of serpentine soil in the environment were mentioned for research needs in the future. |
| Beschreibung: | Application of Serpentine Soils. |
| Beschreibung: | 1 online resource |
| Bibliographie: | Includes bibliographical references and index. |
| ISBN: | 9781536138764 1536138762 |
Internformat
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| 245 | 1 | 0 | |a Biogeochemistry of serpentine soils / |c Zeng-Yei Hseu. |
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| 504 | |a Includes bibliographical references and index. | ||
| 520 | |a Soils have various functions in all ecosystems, particularly for environmental quality and human health. The parent materials of serpentine soils are characterized by much higher contents of elements such as Mg, Fe, Cr, Ni, Co, and Mn, and thus the derived soils display potentially ecological or environmental risk due to high levels of geogenic heavy metals, low concentrations of P and K, low Ca/Mg ratios, unique flora, and unstable landscape. Serpentine soils can be produced by ultramafics alone and also by hydrothermally altered ultramafics in the presence of serpentines, but they are abundant in ophiolite belts along tectonic plate margins. To sustain natural resources such as serpentine soils, we need a better understanding for the impact of serpentine soils on (1) the pedosphere and rhizosphere, (2) ecology and restoration, (3) biogeochemical cycling of elements, (4) environmental quality, crop quality, food safety, and human health, and (5) phyto-accumulation and agromining of heavy metals (i.e., nickel) worldwide. Hence, the purpose of this book is to study the biogeochemical characteristics of serpentine soils. In the beginning, the authors introduce the basic knowledge of these soils including pedogenesis, mineral weathering, morphology, and classification. Moreover, bioavailability, plant uptake, and human health risk were discussed for the enriched heavy metals in serpentine soil. Finally, applications of serpentine soil in the environment were mentioned for research needs in the future. | ||
| 505 | 0 | |a Intro; Contents; Preface; Acknowledgments; Chapter 1; Introduction; Abstract; Soil Functions in Ecosystems; Importance of Serpentine Soil Biogeochemistry; References; Chapter 2; Parent Minerals of Serpentine Soils; Abstract; Ultramafic Rocks; Serpentine Group Minerals; Accessory Serpentine Minerals; Chromite; Discrimination of Parent Material Inheritance by Comparing Elements; References; Chapter 3; Pedogenesis and Classification of Serpentine Soils; Abstract; Introduction; Mountainous Terrain; Colluvium; Alluvium; Pedogenesis in a Chronosequence; Pedogenesis In Toposequences. | |
| 505 | 8 | |a Vosges Mountains, FranceHyogo, Japan; Eastern Taiwan; References; Chapter 4; Mineral Weathering and Transformation; Abstract; Weathering of Primary Minerals; Mineral Transformation of Clay Minerals; Chromite Weathering; References; Chapter 5; Element Enrichment in Serpentine Soils; Abstract; Introduction; Major Elements; Trace Elements; Association of Elements; Soil Sampling and Analysis; Area Description and Sample Collection; Results; General Soil Properties; Total and DTPA-Extractable Amounts of Cr and Ni; Cat, Mgt, Cae, and Mge Concentrations; Discussion. | |
| 505 | 8 | |a Verification of Cr and Ni Origins by Using Total Ca/Mg RatioRelationship between Available Cr and Ni and Exchangeable Ca/Mg Ratio; References; Chapter 6; Availability of Heavy Metals to Plants in Serpentine Soils; Abstract; Introduction; Availability of Chromium and Nickel in a Toposequence; Chromium; Nickel; Nickel Availability in Paddy Soils; Selective Nickel Extractions; Correlation of Nickel with Iron and Manganese Oxides; Cobalt Availability; Abundance of Cobalt; Selective Cobalt Extractions; References; Chapter 7; Release of Heavy Metals in Serpentine Soils; Abstract. | |
| 505 | 8 | |a Kinetics of Nickel DissolutionIntroduction; Experimental Methods of Nickel Dissolution; Proton- and Ligand-Promoted Dissolution of Nickel; Leaching Nickel with Inorganic and Organic Acids; Pedogenic Chromium Associated with Iron and Manganese Oxides; Introduction; Soil Sampling and Analysis at a Serpentine Quarry Site; Various Fractions of Chromium Associated with Iron and Manganese; Elucidating Effects of Fe and Mn Oxides on Cr(VI) Generation; References; Chapter 8; Accumulation of Metals in Plants on Serpentine Soils; Abstract; Introduction. | |
| 505 | 8 | |a Exploration of Metal Accumulation in Wild PlantsMetals in Roots; Metals in Shoots; Chromium and Nickel in Rice; References; Chapter 9; Risk to Human Health from Exposure to Serpentine Soils: A Case Study of Chromium and Nickel Risk in Soil-Rice Systems; Abstract; Introduction; Materials and Methods; Description of Study Sites; Sample Collection and Analysis; Statistical Analyses; Risk Assessment Procedures; Results and Discussion; Concentrations of Chromium and Nickel in Soil, Dust, and Rice; CR; Noncarcinogenic Risk; Uncertainty and Sensitivity of Risk; References; Chapter 10. | |
| 500 | |a Application of Serpentine Soils. | ||
| 588 | 0 | |a Print version of record. | |
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| 650 | 0 | |a Biogeochemistry. |0 http://id.loc.gov/authorities/subjects/sh85014146 | |
| 650 | 6 | |a Sols |x Teneur en serpentine. | |
| 650 | 6 | |a Biogéochimie. | |
| 650 | 7 | |a TECHNOLOGY & ENGINEERING |x Agriculture |x General. |2 bisacsh | |
| 650 | 7 | |a Biogeochemistry |2 fast | |
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Datensatz im Suchindex
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| _version_ | 1816882465864679424 |
| adam_text | |
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| author | Hseu, Zeng-Yei |
| author_facet | Hseu, Zeng-Yei |
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| callnumber-search | S592.6.S45 |
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| contents | Intro; Contents; Preface; Acknowledgments; Chapter 1; Introduction; Abstract; Soil Functions in Ecosystems; Importance of Serpentine Soil Biogeochemistry; References; Chapter 2; Parent Minerals of Serpentine Soils; Abstract; Ultramafic Rocks; Serpentine Group Minerals; Accessory Serpentine Minerals; Chromite; Discrimination of Parent Material Inheritance by Comparing Elements; References; Chapter 3; Pedogenesis and Classification of Serpentine Soils; Abstract; Introduction; Mountainous Terrain; Colluvium; Alluvium; Pedogenesis in a Chronosequence; Pedogenesis In Toposequences. Vosges Mountains, FranceHyogo, Japan; Eastern Taiwan; References; Chapter 4; Mineral Weathering and Transformation; Abstract; Weathering of Primary Minerals; Mineral Transformation of Clay Minerals; Chromite Weathering; References; Chapter 5; Element Enrichment in Serpentine Soils; Abstract; Introduction; Major Elements; Trace Elements; Association of Elements; Soil Sampling and Analysis; Area Description and Sample Collection; Results; General Soil Properties; Total and DTPA-Extractable Amounts of Cr and Ni; Cat, Mgt, Cae, and Mge Concentrations; Discussion. Verification of Cr and Ni Origins by Using Total Ca/Mg RatioRelationship between Available Cr and Ni and Exchangeable Ca/Mg Ratio; References; Chapter 6; Availability of Heavy Metals to Plants in Serpentine Soils; Abstract; Introduction; Availability of Chromium and Nickel in a Toposequence; Chromium; Nickel; Nickel Availability in Paddy Soils; Selective Nickel Extractions; Correlation of Nickel with Iron and Manganese Oxides; Cobalt Availability; Abundance of Cobalt; Selective Cobalt Extractions; References; Chapter 7; Release of Heavy Metals in Serpentine Soils; Abstract. Kinetics of Nickel DissolutionIntroduction; Experimental Methods of Nickel Dissolution; Proton- and Ligand-Promoted Dissolution of Nickel; Leaching Nickel with Inorganic and Organic Acids; Pedogenic Chromium Associated with Iron and Manganese Oxides; Introduction; Soil Sampling and Analysis at a Serpentine Quarry Site; Various Fractions of Chromium Associated with Iron and Manganese; Elucidating Effects of Fe and Mn Oxides on Cr(VI) Generation; References; Chapter 8; Accumulation of Metals in Plants on Serpentine Soils; Abstract; Introduction. Exploration of Metal Accumulation in Wild PlantsMetals in Roots; Metals in Shoots; Chromium and Nickel in Rice; References; Chapter 9; Risk to Human Health from Exposure to Serpentine Soils: A Case Study of Chromium and Nickel Risk in Soil-Rice Systems; Abstract; Introduction; Materials and Methods; Description of Study Sites; Sample Collection and Analysis; Statistical Analyses; Risk Assessment Procedures; Results and Discussion; Concentrations of Chromium and Nickel in Soil, Dust, and Rice; CR; Noncarcinogenic Risk; Uncertainty and Sensitivity of Risk; References; Chapter 10. |
| ctrlnum | (OCoLC)1044967381 |
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| dewey-ones | 631 - Techniques, equipment & materials |
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| dewey-search | 631.4/1 |
| dewey-sort | 3631.4 11 |
| dewey-tens | 630 - Agriculture and related technologies |
| discipline | Agrar-/Forst-/Ernährungs-/Haushaltswissenschaft / Gartenbau |
| format | Electronic eBook |
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| id | ZDB-4-EBA-on1044967381 |
| illustrated | Not Illustrated |
| indexdate | 2024-11-27T13:29:03Z |
| institution | BVB |
| isbn | 9781536138764 1536138762 |
| language | English |
| oclc_num | 1044967381 |
| open_access_boolean | |
| owner | MAIN DE-863 DE-BY-FWS |
| owner_facet | MAIN DE-863 DE-BY-FWS |
| physical | 1 online resource |
| psigel | ZDB-4-EBA |
| publishDate | 2018 |
| publishDateSearch | 2018 |
| publishDateSort | 2018 |
| publisher | Nova Science Publishers, Incorporated, |
| record_format | marc |
| series | Environmental science, engineering and technology series. Environmental Science, Engineering and Technology Ser. |
| series2 | Environmental science, engineering and technology series |
| spelling | Hseu, Zeng-Yei. Biogeochemistry of serpentine soils / Zeng-Yei Hseu. New York : Nova Science Publishers, Incorporated, 2018. 1 online resource text txt rdacontent computer c rdamedia online resource cr rdacarrier Environmental science, engineering and technology series Includes bibliographical references and index. Soils have various functions in all ecosystems, particularly for environmental quality and human health. The parent materials of serpentine soils are characterized by much higher contents of elements such as Mg, Fe, Cr, Ni, Co, and Mn, and thus the derived soils display potentially ecological or environmental risk due to high levels of geogenic heavy metals, low concentrations of P and K, low Ca/Mg ratios, unique flora, and unstable landscape. Serpentine soils can be produced by ultramafics alone and also by hydrothermally altered ultramafics in the presence of serpentines, but they are abundant in ophiolite belts along tectonic plate margins. To sustain natural resources such as serpentine soils, we need a better understanding for the impact of serpentine soils on (1) the pedosphere and rhizosphere, (2) ecology and restoration, (3) biogeochemical cycling of elements, (4) environmental quality, crop quality, food safety, and human health, and (5) phyto-accumulation and agromining of heavy metals (i.e., nickel) worldwide. Hence, the purpose of this book is to study the biogeochemical characteristics of serpentine soils. In the beginning, the authors introduce the basic knowledge of these soils including pedogenesis, mineral weathering, morphology, and classification. Moreover, bioavailability, plant uptake, and human health risk were discussed for the enriched heavy metals in serpentine soil. Finally, applications of serpentine soil in the environment were mentioned for research needs in the future. Intro; Contents; Preface; Acknowledgments; Chapter 1; Introduction; Abstract; Soil Functions in Ecosystems; Importance of Serpentine Soil Biogeochemistry; References; Chapter 2; Parent Minerals of Serpentine Soils; Abstract; Ultramafic Rocks; Serpentine Group Minerals; Accessory Serpentine Minerals; Chromite; Discrimination of Parent Material Inheritance by Comparing Elements; References; Chapter 3; Pedogenesis and Classification of Serpentine Soils; Abstract; Introduction; Mountainous Terrain; Colluvium; Alluvium; Pedogenesis in a Chronosequence; Pedogenesis In Toposequences. Vosges Mountains, FranceHyogo, Japan; Eastern Taiwan; References; Chapter 4; Mineral Weathering and Transformation; Abstract; Weathering of Primary Minerals; Mineral Transformation of Clay Minerals; Chromite Weathering; References; Chapter 5; Element Enrichment in Serpentine Soils; Abstract; Introduction; Major Elements; Trace Elements; Association of Elements; Soil Sampling and Analysis; Area Description and Sample Collection; Results; General Soil Properties; Total and DTPA-Extractable Amounts of Cr and Ni; Cat, Mgt, Cae, and Mge Concentrations; Discussion. Verification of Cr and Ni Origins by Using Total Ca/Mg RatioRelationship between Available Cr and Ni and Exchangeable Ca/Mg Ratio; References; Chapter 6; Availability of Heavy Metals to Plants in Serpentine Soils; Abstract; Introduction; Availability of Chromium and Nickel in a Toposequence; Chromium; Nickel; Nickel Availability in Paddy Soils; Selective Nickel Extractions; Correlation of Nickel with Iron and Manganese Oxides; Cobalt Availability; Abundance of Cobalt; Selective Cobalt Extractions; References; Chapter 7; Release of Heavy Metals in Serpentine Soils; Abstract. Kinetics of Nickel DissolutionIntroduction; Experimental Methods of Nickel Dissolution; Proton- and Ligand-Promoted Dissolution of Nickel; Leaching Nickel with Inorganic and Organic Acids; Pedogenic Chromium Associated with Iron and Manganese Oxides; Introduction; Soil Sampling and Analysis at a Serpentine Quarry Site; Various Fractions of Chromium Associated with Iron and Manganese; Elucidating Effects of Fe and Mn Oxides on Cr(VI) Generation; References; Chapter 8; Accumulation of Metals in Plants on Serpentine Soils; Abstract; Introduction. Exploration of Metal Accumulation in Wild PlantsMetals in Roots; Metals in Shoots; Chromium and Nickel in Rice; References; Chapter 9; Risk to Human Health from Exposure to Serpentine Soils: A Case Study of Chromium and Nickel Risk in Soil-Rice Systems; Abstract; Introduction; Materials and Methods; Description of Study Sites; Sample Collection and Analysis; Statistical Analyses; Risk Assessment Procedures; Results and Discussion; Concentrations of Chromium and Nickel in Soil, Dust, and Rice; CR; Noncarcinogenic Risk; Uncertainty and Sensitivity of Risk; References; Chapter 10. Application of Serpentine Soils. Print version of record. Soils Serpentine content. http://id.loc.gov/authorities/subjects/sh87006248 Biogeochemistry. http://id.loc.gov/authorities/subjects/sh85014146 Sols Teneur en serpentine. Biogéochimie. TECHNOLOGY & ENGINEERING Agriculture General. bisacsh Biogeochemistry fast Soils Serpentine content fast Print version: Hseu, Zeng-Yei. Biogeochemistry of Serpentine Soils. New York : Nova Science Publishers, Incorporated, ©2018 9781536131710 Environmental science, engineering and technology series. http://id.loc.gov/authorities/names/no2009145261 Environmental Science, Engineering and Technology Ser. FWS01 ZDB-4-EBA FWS_PDA_EBA https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=1855201 Volltext |
| spellingShingle | Hseu, Zeng-Yei Biogeochemistry of serpentine soils / Environmental science, engineering and technology series. Environmental Science, Engineering and Technology Ser. Intro; Contents; Preface; Acknowledgments; Chapter 1; Introduction; Abstract; Soil Functions in Ecosystems; Importance of Serpentine Soil Biogeochemistry; References; Chapter 2; Parent Minerals of Serpentine Soils; Abstract; Ultramafic Rocks; Serpentine Group Minerals; Accessory Serpentine Minerals; Chromite; Discrimination of Parent Material Inheritance by Comparing Elements; References; Chapter 3; Pedogenesis and Classification of Serpentine Soils; Abstract; Introduction; Mountainous Terrain; Colluvium; Alluvium; Pedogenesis in a Chronosequence; Pedogenesis In Toposequences. Vosges Mountains, FranceHyogo, Japan; Eastern Taiwan; References; Chapter 4; Mineral Weathering and Transformation; Abstract; Weathering of Primary Minerals; Mineral Transformation of Clay Minerals; Chromite Weathering; References; Chapter 5; Element Enrichment in Serpentine Soils; Abstract; Introduction; Major Elements; Trace Elements; Association of Elements; Soil Sampling and Analysis; Area Description and Sample Collection; Results; General Soil Properties; Total and DTPA-Extractable Amounts of Cr and Ni; Cat, Mgt, Cae, and Mge Concentrations; Discussion. Verification of Cr and Ni Origins by Using Total Ca/Mg RatioRelationship between Available Cr and Ni and Exchangeable Ca/Mg Ratio; References; Chapter 6; Availability of Heavy Metals to Plants in Serpentine Soils; Abstract; Introduction; Availability of Chromium and Nickel in a Toposequence; Chromium; Nickel; Nickel Availability in Paddy Soils; Selective Nickel Extractions; Correlation of Nickel with Iron and Manganese Oxides; Cobalt Availability; Abundance of Cobalt; Selective Cobalt Extractions; References; Chapter 7; Release of Heavy Metals in Serpentine Soils; Abstract. Kinetics of Nickel DissolutionIntroduction; Experimental Methods of Nickel Dissolution; Proton- and Ligand-Promoted Dissolution of Nickel; Leaching Nickel with Inorganic and Organic Acids; Pedogenic Chromium Associated with Iron and Manganese Oxides; Introduction; Soil Sampling and Analysis at a Serpentine Quarry Site; Various Fractions of Chromium Associated with Iron and Manganese; Elucidating Effects of Fe and Mn Oxides on Cr(VI) Generation; References; Chapter 8; Accumulation of Metals in Plants on Serpentine Soils; Abstract; Introduction. Exploration of Metal Accumulation in Wild PlantsMetals in Roots; Metals in Shoots; Chromium and Nickel in Rice; References; Chapter 9; Risk to Human Health from Exposure to Serpentine Soils: A Case Study of Chromium and Nickel Risk in Soil-Rice Systems; Abstract; Introduction; Materials and Methods; Description of Study Sites; Sample Collection and Analysis; Statistical Analyses; Risk Assessment Procedures; Results and Discussion; Concentrations of Chromium and Nickel in Soil, Dust, and Rice; CR; Noncarcinogenic Risk; Uncertainty and Sensitivity of Risk; References; Chapter 10. Soils Serpentine content. http://id.loc.gov/authorities/subjects/sh87006248 Biogeochemistry. http://id.loc.gov/authorities/subjects/sh85014146 Sols Teneur en serpentine. Biogéochimie. TECHNOLOGY & ENGINEERING Agriculture General. bisacsh Biogeochemistry fast Soils Serpentine content fast |
| subject_GND | http://id.loc.gov/authorities/subjects/sh87006248 http://id.loc.gov/authorities/subjects/sh85014146 |
| title | Biogeochemistry of serpentine soils / |
| title_auth | Biogeochemistry of serpentine soils / |
| title_exact_search | Biogeochemistry of serpentine soils / |
| title_full | Biogeochemistry of serpentine soils / Zeng-Yei Hseu. |
| title_fullStr | Biogeochemistry of serpentine soils / Zeng-Yei Hseu. |
| title_full_unstemmed | Biogeochemistry of serpentine soils / Zeng-Yei Hseu. |
| title_short | Biogeochemistry of serpentine soils / |
| title_sort | biogeochemistry of serpentine soils |
| topic | Soils Serpentine content. http://id.loc.gov/authorities/subjects/sh87006248 Biogeochemistry. http://id.loc.gov/authorities/subjects/sh85014146 Sols Teneur en serpentine. Biogéochimie. TECHNOLOGY & ENGINEERING Agriculture General. bisacsh Biogeochemistry fast Soils Serpentine content fast |
| topic_facet | Soils Serpentine content. Biogeochemistry. Sols Teneur en serpentine. Biogéochimie. TECHNOLOGY & ENGINEERING Agriculture General. Biogeochemistry Soils Serpentine content |
| url | https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=1855201 |
| work_keys_str_mv | AT hseuzengyei biogeochemistryofserpentinesoils |